JPH0851412A - Passive point-multipoint optical transmission system - Google Patents

Abstract

(57) [Abstract] [Objective] A passive point-to-multipoint optical transmission system configured to modulate and return light transmitted from a center device without disposing an active optical element in a user device, and to reduce transmission efficiency. Overlap of upstream optical signals from a plurality of user equipments to the center equipment is avoided while minimizing. A center device is provided with an optical transmitting unit for time-division multiplexing and transmitting a downstream optical signal to each user device, and an optical receiving unit for receiving an upstream optical signal from each user device. A center device comprising optical receiving means for receiving the downlink optical signals in the respectively allocated time regions, and optical transmitting means for modulating the downlink optical signal itself or a part of the downlink optical signal and transmitting the modulated uplink optical signal. Alternatively, at least one of the user equipments is provided with control means for controlling the transmission timing of the downlink optical signal or the uplink optical signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a point-multipoint optical transmission system for communicating between a center device and a plurality of user devices which are opposed to each other via an optical transmission line. In particular, the present invention relates to a passive point-to-multipoint optical transmission system configured to modulate and return light transmitted from a center device without disposing an active optical element in a user device.

[0002]

2. Description of the Related Art FIG. 16 is a block diagram showing the configuration of a conventional passive point-multipoint optical transmission system. Here, as a passive optical transmission technique, a case of performing one-fiber optical fiber transmission using a reflecting element is shown.

In the figure, a center device 20 and N user devices 30-1 to 30-N are represented by a 1-to-N optical star coupler 1.
The optical fiber 11 is connected to the feeder optical fiber 11 via N branch optical fibers 12-1 to 12-N. Center device 20
Is composed of a transmitter 21, a receiver 22 and a one-to-two optical coupler (or optical circulator) 23. Each user device 30 includes a receiving unit 31, a reflecting unit 32, and a one-to-two optical coupler 33.

The operation of the conventional system will now be described with reference to the transmission / reception diagram shown in FIG. The center device 20 time-division-multiplexes the downstream optical signals D1 to DN to the user devices 30-1 to 30-N, and sends them from the one-to-two optical coupler 23 to the feeder optical fiber 11. In each of the downlink optical signals D1 to DN, the signal light to each user equipment and the modulated light modulated by each user equipment are multiplexed in the time domain assigned to each user equipment. DC light, for example, is used as the modulated signal. Each downlink optical signal D1 to DN is 1
The N-to-N optical star coupler 10 branches into N, and each of the user equipments 30-1 to 30-3 through the branch optical fibers 12-1 to 12-N.
It is transmitted in a broadcast format to 0-N.

In the user device 30-1, the received signal is input to the receiving section 31 and the reflecting section 32 via the one-to-two optical coupler 33. The receiving unit 31 receives the signal light addressed to the own device from the allocated downlink optical signal D1 in the time domain. The reflecting unit 32 modulates the modulated light addressed to the own device and outputs the upstream optical signal U.
1 is generated and sent to the branch optical fiber 12-1 via the 1-to-2 optical coupler 33. It should be noted that no light other than the modulated light addressed to the own device is modulated. The same applies to the other user devices 30-2 to 30-N.

The upstream optical signals U1 to UN transmitted from the respective user equipments 30-1 to 30-N are merged by the 1-to-N optical star coupler 10 and transmitted to the center equipment 20 via the feeder optical fiber 11. It In the center device 20, the upstream optical signals U1 to UN are received by the receiving unit 22 via the 1: 2 optical coupler 23.
To be received. Note that, for simplification, the sync bit for synchronizing the optical signals is omitted in FIG.

[0007]

In the passive point-multipoint optical transmission system, the transmission timing of the upstream optical signal of the user equipment is restricted by the reception timing of the downstream optical signal. On the other hand, since the round-trip propagation delay time differs depending on the distance between the center apparatus and each user apparatus, the upstream optical signals from each user apparatus may overlap when they reach the center apparatus.

In the transmission / reception diagram shown in FIG. 17, the distance from the center device 20 to each of the user devices 30-1 to 30-N increases in order, and the arrangement of the downstream optical signals D1 to DN to each user device is arranged. Since it corresponds to this, the center device 20 has the upstream optical signals U1 to U1 from the respective user devices.
UNs are received in order.

However, when the distance from the center device 20 to the user device 30-1 and the distance to the user device 30-2 are reversed as shown in the transmission / reception diagram shown in FIG.
The upstream optical signal U2 from the user equipment 30-2 overlaps with the upstream optical signal U1 from the user equipment 30-1. In such a case, the center device 20 cannot receive normally.

The present invention provides a passive point-to-multipoint optical transmission system capable of avoiding overlapping of upstream optical signals from a plurality of user equipments to a center equipment while minimizing a decrease in transmission efficiency. The purpose is to

[0011]

The passive point-to-multipoint optical transmission system of the present invention comprises an optical transmission means for time-divisionally transmitting a downstream optical signal to each user equipment to a center equipment, and each user. An optical receiving means for receiving an upstream optical signal from the device, and an optical receiving means for receiving a downstream optical signal in a time domain assigned to each user equipment, and the downstream optical signal itself or one of the downstream optical signals. And a light transmitting unit that modulates the unit and transmits it as an upstream optical signal,
At least one of the center device and each user device is provided with control means for controlling the transmission timing of the downstream optical signal or the upstream optical signal.

Further, the control means sets the maximum round-trip propagation between the center apparatus and each user apparatus as a guard time between each downlink optical signal in the downlink frame in which the downlink optical signal to each user apparatus is time division multiplexed. This is a configuration for setting the delay time.

Further, the control means, between the downlink optical signal to the i-th user apparatus and the downlink optical signal to the (i + 1) th user apparatus, in the downlink frame obtained by time-division multiplexing the downlink optical signal to each user apparatus. As the guard time for
The configuration is set according to the round-trip propagation delay time with the second user device.

The control means determines the time width of the downlink optical signal to each user equipment and the time width of the uplink optical signal from each user equipment as the maximum round trip propagation delay time between the center equipment and each user equipment. It is configured to set a shorter value, and to set the transmission timing according to the round-trip propagation delay time with each user equipment in the downstream optical signal to each user equipment. Further, the above passive point-multipoint optical transmission In the system, the optical transmission means of the center device is configured to generate the downlink optical signal to each user equipment by using the phase modulation code, and the optical transmission means of each user equipment is the phase modulation code of the received downlink optical signal. Is amplitude-modulated to generate an upstream optical signal.

Further, the optical transmission means of the center device time-division-multiplexes the signal light to each user equipment and the modulated light modulated by each user equipment to generate a downstream optical signal to each user equipment. The control means is configured to set the time width of the signal light of the downlink optical signal to each user apparatus to the maximum round trip propagation delay time between the center apparatus and each user apparatus. The optical transmitting means is configured to modulate the modulated light of the downstream optical signal and generate the upstream optical signal.

Further, the optical transmission means of the center device is configured to time-division-multiplex the downstream optical signal to each user device, and further superimpose and transmit the DC light in the entire time region thereof. The transmitting means is configured to modulate the received direct-current light and generate an upstream optical signal, and the control means is configured to set the generation timing of the upstream optical signal in the time domain assigned to each user apparatus.

Further, the optical transmission means of the center device uses the phase modulation code to generate a downstream optical signal to each user device,
The configuration is for time-division multiplexing and transmission, and the optical transmission means of each user equipment is configured to amplitude-modulate the phase modulation code of the received downstream optical signal to generate an upstream optical signal. In the configuration, the signal generation timing is set in the time domain assigned to each user apparatus.

[0018]

In the passive point-to-multipoint optical transmission system of the present invention, the transmission timing of the downstream optical signal from the center device to each user device or the transmission timing of the upstream optical signal from each user device to the center device is controlled. As a result, the upstream optical signals from the respective user equipments can be prevented from overlapping at the center equipment (claim 1).

By setting the maximum round-trip propagation delay time between the center apparatus and each user apparatus as the guard time between the downstream optical signals to each user apparatus, each user apparatus or the downlink optical signal itself is set. Even if the parts are modulated and folded back, the upstream optical signals can be prevented from overlapping in the center device (claim 2).

The guard time corresponding to each user equipment is set according to the round-trip propagation delay time with each user equipment so that the upstream optical signals do not overlap at the center equipment with a minimum guard time. It is possible (Claim 3).

The time widths of the downlink optical signal and the uplink optical signal are set to values shorter than the maximum round-trip propagation delay time with each user apparatus, and the downlink optical signal to each user apparatus is set to a value shorter than the maximum round-trip propagation delay time with each user apparatus. By setting the transmission timing according to the round-trip propagation delay time, the upstream optical signal from each user apparatus becomes independent of the array in the downlink frame, so the degree of freedom in the array of upstream optical signals is increased (claim 4). .

In the passive point-to-multipoint optical transmission system described above, a downlink optical signal to each user equipment is generated by using a phase modulation code, and the phase modulation code of the downlink optical signal is amplitude-modulated to generate an upstream optical signal. By generating, it is not necessary to send the modulated light for generating the upstream optical signal to each user equipment (claim 5).

Further, the signal light and the modulated light are time-division multiplexed to generate a downstream optical signal to each user equipment, and the time width of the signal light is set to the maximum round trip propagation delay time with each user equipment. By setting, the guard time between each downlink optical signal can be made unnecessary (claim 6).

Further, direct-current light is superimposed on the downstream optical signal to each user equipment and transmitted, and each user equipment modulates the direct-current light at a predetermined timing to generate an upstream optical signal. Accordingly, each user apparatus can set the transmission timing of each upstream optical signal regardless of the reception timing of the downstream optical signal (claim 7).

Further, the downlink optical signal to each user equipment by the phase modulation code is time division multiplexed and transmitted, and each user equipment amplitude-modulates the phase modulation code at a predetermined timing to generate an upstream optical signal. Accordingly, each user apparatus can set the transmission timing of each upstream optical signal regardless of the reception timing of the downstream optical signal (claim 8).

[0026]

FIG. 1 is a block diagram showing the configuration of the embodiment of claim 1. FIG. 2 is a transmission / reception diagram showing the embodiment of claim 2.

In the figure, a transmission unit 21 is provided in the center device 20.
A control unit 24 is provided for controlling the transmission timing of.
Others are the same as the conventional configuration shown in FIG. The center device 20 has the respective user devices 30-1 to 30-3 prior to communication.
The round trip propagation delay time τ _{1 to} τ N between 0 and _N is measured. For this measurement, for example, a method of transmitting an optical signal to each user apparatus and observing the arrival time of the optical signal returned as a response is adopted. In the present embodiment, the maximum value τ of the round-trip propagation delay time with each user apparatus in the downlink frame in which the downlink optical signals D1 to DN to each user apparatus are time division multiplexed.
_MAX is used as the guard time T of each downstream optical signal D1 to DN. Thereby, each of the user devices 30-1 to 30-
The round-trip propagation delay times τ _{1 to} τ _{N with N} are less than or equal to the guard time T (= τ _MAX ), and the upstream optical signals U1 to UN from the respective user equipments do not overlap. In this example, since the guard time between each downlink optical signal is constant,
The transmission timing control in the control unit 24 can be realized with a simple configuration.

FIG. 3 is a transmission / reception diagram showing an embodiment of claim 3. Center device 20 measures the round-trip propagation delay τ ₁ ~τ _N between the user apparatuses 30-1 to 30-N in a similar manner. The downlink optical signals D1 to DN
It is used as the guard time T _{1 to TN} . For example,
The round-trip propagation delay time τ ₁ with the user equipment 30-1 is used as the guard time T ₁ between the downstream optical signals D1 and D2. As a result, since the downstream optical signal D (i + 1) to the user equipment 30- (i + 1) is transmitted after the upstream optical signal Ui from the user equipment 30-i arrives, the upstream optical signal from each user equipment is transmitted. U1 to UN do not overlap. Moreover, since the guard time T ₁ through T _N are set according to the propagation delay between the user apparatuses, it is possible to increase the transmission efficiency. Note that each guard time is τ ₁ −
τ ₂ , τ _{2 −} τ ₃ , ,, τ _{N −} τ ₁ (0 if negative)
With this, it is possible to further improve the transmission efficiency.

FIG. 4 is a block diagram showing the configuration of another embodiment of the first aspect. The present embodiment is characterized in that the center device 20 and each of the user devices 30-1 to 30-N are connected in a time division manner using an optical switch 25. As a result, only the downlink optical signal addressed to the user equipment is transmitted to each user equipment. In addition, 1 to N optical star coupler 1
Since there is no distribution loss generated at 0, the output light intensity from the center device can be reduced.

Similar to the transmission / reception diagrams shown in FIGS. 2 and 3, the transmission / reception diagram of this embodiment sets a predetermined guard time between each of the downlink optical signals D1 to DN so that transmission / reception with each user device can be performed individually. The optical switch 25 is sequentially switched at the timing when it is performed. Here, FIG. 5 shows a transmission / reception diagram when each guard time is appropriately set (corresponding to FIG. 3).

FIG. 6 is a block diagram showing the configuration of the embodiment of claim 4. FIG. 7 is a transmission / reception diagram showing an embodiment of claim 4. In the figure, in the center device 20,
Control unit 24a that controls the transmission timing of the transmission unit 21
And a control unit 24b that replaces the received signal array in the reception unit 22. Others are the same as the configuration of the embodiment shown in FIG.

In this embodiment, each user device 30-1 to 30-3 is used.
The time width of the downstream optical signals D1 to DN to 0-N and the upstream optical signals U1 to U from each of the user equipments 30-1 to 30-N.
The time width of N is set to a value shorter than the maximum value τ _MAX of the round-trip propagation delay time with each user equipment. As a result, depending on the round-trip propagation delay time with each user equipment, when the upstream optical signal with respect to the downstream optical signal to each user equipment arrives at the center equipment, there is a possibility of overlapping or replacement. Become.

In the center device 20, each user device 30-
Using the round trip propagation delay τ ₁ ~τ _N between the 1 to 30-N, to calculate the reception timing of the uplink optical signal based on the timing of transmitting a downlink optical signal. Here, when it is expected that the upstream optical signals from a plurality of user equipments overlap, the control unit 24a performs control to advance or delay the transmission timing of the downstream optical signals to the corresponding user equipments. Further, in setting the transmission timing, it is possible to expand the control range of the transmission timing by changing the arrangement of the downlink optical signals to each user apparatus. By performing such transmission timing setting for each user apparatus, it is possible to prevent the upstream optical signals from each user apparatus from overlapping each other. The transmission unit 21 starts transmission of the downlink optical signal according to the transmission timing of each user apparatus.

In the transmission / reception diagram shown in FIG. 7, it is assumed that the user devices 30-2, 30-3 and 30-1 are located in the distant order. Since the time width of the downlink optical signal and the uplink optical signal is sufficiently shorter than the maximum value τ _MAX of the round-trip propagation delay time with each user apparatus, before the uplink optical signal U1 from the user apparatus 30-1 arrives. , The upstream optical signal U2 from the user apparatus 30-2 located at a shorter distance than that arrives. A guard time is set so that the upstream optical signals U1 to UN from the respective user equipments do not overlap each other and are normally received.

In the present embodiment, the upstream optical signals U1 to UN received from the respective user equipments by the center equipment 20 are irrelevant to the arrangement in the downstream frame according to the round-trip propagation delay time with the respective user equipments. Therefore, the degree of freedom of arrangement of the upstream optical signals is increased, and more efficient transmission is possible. The control unit 24b performs control to return the upstream optical signals U1 to UN received by the receiving unit 22 from each user device to a predetermined array.

The upstream optical signal U1 from each user equipment
~ UN may not be overlapped, and the downlink optical signals D1 to DN may be exchanged and transmitted so as to have a predetermined array. A transmission / reception diagram in this case is shown in FIG.

In the above embodiment, the receiving unit 31 and the reflecting unit 32 of the user device are separate elements, but a reflection type photodetector modulator in which they are integrated may be used. A reflection-type photodetector modulator is a stack of a photodetector, an optical modulator, and a reflector.The incident light is received by the photodetector, and part of the light is reflected and modulated by the optical modulator. It is a structure that emits light by folding back.

Further, although the above-mentioned embodiment has the one-fiber optical fiber transmission structure using the reflecting element, the user equipment is provided with the transmissive photodetector modulator and the two optical fibers are divided into the downstream and the upstream. A transmission configuration can also be used. The transmissive photodetector modulator is a stack of a photodetector and a photomodulator, and has a structure in which incident light is received by the photodetector and transmitted light is modulated by the photomodulator and emitted.

Here, in the configuration of the embodiment of FIG. 4 (FIG. 6), an optical fiber two-fiber transmission configuration using a transmission type photodetector modulator and the 1-to-N optical star coupler 10 is replaced with an optical switch. Is shown in FIG. Reference numeral 34 is a transmissive photodetector modulator, 12-1a to 12-Na are branch optical fibers that transmit downstream optical signals, and 12-1b to 12-Nb are branch optical fibers that transmit upstream optical signals. .

In the embodiment of claim 4, since the downstream optical signal and the upstream optical signal are completely independent on the time axis, the optical switch 25a for switching the downstream optical signal and the optical switch for switching the upstream optical signal are used. The optical switch 25b is separately provided, and the switching operation is performed at each independent timing. A transmission / reception diagram of this embodiment is shown in FIG.

The above is the basic configuration and transmission / reception diagram of the passive point-multipoint optical transmission system of the present invention. Next, the downlink optical signal Di to each user equipment
And the method of generating the upstream optical signal Ui from the downstream optical signal Di.

FIG. 11 is a block diagram showing the configuration of the embodiment of claim 5. In the present embodiment, a phase modulation code is used as the downlink optical signals D1 to DN to each user equipment, and the phase modulation code is amplitude-modulated R as the uplink optical signals U1 to UN.
The Z code is used. The phase modulation code is, for example, a biphase code that associates two types of positive and negative or negative and positive pulses with a "1" or "0" signal.

In the center device 20, the phase modulator (PMO
D) 26 drives the transmitter 21 to generate downlink optical signals D1 to DN to each user equipment by using the phase modulation code. In each of the user devices 30-1 to 30-N, the phase demodulation unit (PDEM) 35 demodulates the phase modulation code received by the reception unit 31. In addition, the amplitude modulator (AMOD) 36 is provided in the reflector 3
2 is driven and the received phase modulation code is amplitude-modulated to generate upstream optical signals U1 to UN to the center device. In the center device 20, the amplitude modulation signal received by the reception unit 22 is demodulated by the amplitude demodulation unit (ADEM) 27.

FIG. 12 is a transmission / reception diagram showing an embodiment of claim 6. The center device 20 time-division-multiplexes the signal lights d1 to dN to the user devices and the modulated lights m1 to mN modulated by the user devices, respectively, and outputs the downstream optical signals D1 to DN to the user devices. To generate. Each of the user equipments 30-1 to 30-N receives the signal light d1 to dN addressed to each user equipment from the downstream optical signals D1 to DN and modulates the modulated light m1 to mN to obtain the upstream optical signals U1 to UN. To generate.

Here, the time width of the signal lights d1 to dN is set to the maximum round trip propagation delay time between the center apparatus and each user apparatus. As a result, the time domain of the signal lights d1 to dN becomes the guard time between the upstream optical signals from each user equipment in the center equipment. Therefore, in the downlink frame, it is not necessary to set the guard time between the downlink optical signals to each user equipment.

FIG. 13 is a block diagram showing the configuration of the embodiment of claim 7. FIG. 14 is a transmission / reception diagram showing an embodiment of claim 7. Transmitter 21 of the center device 20
Is a downlink optical signal D to each of the user equipments 30-1 to 30-N.
1 to DN are time-division multiplexed, and the direct-current superimposing unit 28 superimposes direct-current light in the entire time region.

Each of the user equipments 30-1 to 30-N receives the downstream optical signal addressed to itself, and the filter 37
The direct-current light component extracted via the
A predetermined time domain is modulated to generate upstream optical signals U1 to UN. The time region (transmission timing) designated for each user device is notified from the center device 20 according to the round-trip propagation delay time with each user device. For example, a control channel that specifies the transmission timing of the upstream optical signal is multiplexed in the downstream optical signals D1 to DN to each user equipment. Each user apparatus receives this control channel and drives the reflector 32 in the time domain corresponding to the designated transmission timing. As a result, in each user equipment, the downlink optical signal D1
~ Each upstream optical signal U regardless of the reception timing of DN
Since the transmission timing of 1 to UN can be set, high transmission efficiency can be realized. In addition, for simplicity, FIG.
4, the control channel is omitted.

FIG. 15 is a transmission / reception diagram showing an embodiment of claim 8. The center device 20 uses phase modulation codes as the downlink optical signals D1 to DN to the respective user devices, and time-division-multiplexes them for transmission.

Each of the user equipments 30-1 to 30-N receives the downlink optical signal addressed to itself, and amplitudes the predetermined time domain with respect to the phase modulation code of the entire time domain of the received downlink optical signal. The modulated optical signals U1 to UN are generated. The time region (transmission timing) designated for each user device is notified from the center device 20 as described above. Thereby, in each user equipment, the downlink optical signals D1 to
Regardless of the reception timing of DN, each upstream optical signal U1
Since the transmission timings of ~ UN can be set, high transmission efficiency can be realized. Note that, for simplicity, FIG.
The control channel is omitted in.

[0050]

As described above, in the passive point-to-multipoint optical transmission system of the present invention, the center device controls the transmission timing of the downstream optical signal by providing the guard time so that each user device can control the transmission timing. It is possible to prevent the upstream optical signals from overlapping at the center device. Further, by appropriately setting the guard time in accordance with the round-trip propagation delay time with each user apparatus, the guard time can be suppressed to the necessary minimum and the transmission efficiency can be improved.

Further, in the configuration in which the arrangement of the downstream optical signals and the arrangement of the upstream optical signals are irrelevant, the transmission timing of the downstream optical signals to each user equipment is adjusted to prevent the upstream optical signals from overlapping and It is possible to increase the degree of freedom of transmission and increase the transmission efficiency.

Further, in the configuration in which the downlink optical signal is generated using the phase modulation code and the phase modulation code is amplitude-modulated to generate the upstream optical signal, the modulated signal for generating the upstream optical signal is generated in each user equipment. Since it is not necessary to send light, the transmission efficiency can be improved.

Further, the signal light and the modulated light are time-division-multiplexed to generate a downstream optical signal, and the time width of the signal light is set to the maximum round trip propagation delay time. Time can be eliminated and transmission efficiency can be improved.

Further, by transmitting DC light as modulated light to each user apparatus over the entire time domain of the downlink frame and transmitting the same, regardless of the reception timing of the downlink optical signal on each user apparatus side, The transmission timing of the optical signal can be set. As a result, the upstream optical signals from the respective user equipments can be prevented from overlapping at the center equipment, and the guard time can be eliminated, so that the transmission efficiency can be improved.

Further, in the configuration in which each user equipment amplitude-modulates the phase modulation code to generate the upstream optical signal, the phase modulation code over the entire time domain of the downstream frame can be treated in the same manner as DC light. That is, regardless of the reception timing of the downlink optical signal on the side of each user equipment, since it is possible to set the transmission timing of the uplink optical signal, it is possible to prevent the uplink optical signal from each user equipment from overlapping in the center device,
The guard time can be eliminated and the transmission efficiency can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of claim 1.

FIG. 2 is a transmission / reception diagram showing an embodiment of claim 2;

FIG. 3 is a transmission / reception diagram showing an embodiment of claim 3;

FIG. 4 is a block diagram showing the configuration of another embodiment of claim 1.

5 is a transmission / reception diagram corresponding to the configuration of the embodiment of FIG.

FIG. 6 is a block diagram showing a configuration of an embodiment of claim 4;

FIG. 7 is a transmission / reception diagram showing an embodiment of claim 4;

FIG. 8 is a transmission / reception diagram showing another embodiment of claim 4.

FIG. 9 is a block diagram showing the configuration of another embodiment of claim 4;

10 is a transmission / reception diagram corresponding to the configuration of the embodiment of FIG.

FIG. 11 is a block diagram showing the configuration of an embodiment of claim 5;

FIG. 12 is a transmission / reception diagram showing an embodiment of claim 6;

FIG. 13 is a block diagram showing the configuration of an embodiment of claim 7;

FIG. 14 is a transmission / reception diagram showing an embodiment of claim 7;

FIG. 15 is a transmission / reception diagram showing an embodiment of claim 8;

FIG. 16 is a block diagram showing the configuration of a conventional passive point-to-multipoint optical transmission system.

FIG. 17 is a conventional transmission / reception diagram.

FIG. 18 is a transmission / reception diagram showing conventional problems.

[Explanation of symbols]

 10 1-to-N optical star coupler 11 feeder optical fiber 12 branch optical fiber 20 center device 21 transmitter 22 receiver 23 1-to-2 optical coupler 24 controller 25 optical switch 26 phase modulator (PMOD) 27 amplitude demodulator (ADEM) ) 28 DC superimposing unit 30 User device 31 Receiving unit 32 Reflecting unit 33 One-to-two optical coupler 34 Transmissive photodetector modulator 35 Phase demodulating unit (PDEM) 36 Amplitude modulating unit (AMOD) 37 Filter

Claims (8)

[Claims] 1. A center device and a plurality of user devices are connected in a point-multipoint form via an optical transmission line,
In a passive point-multipoint optical transmission system for bidirectionally transmitting transmission signals of a plurality of user equipments by time division multiplexing, an optical transmission for time-division-multiplexing and transmitting downstream optical signals to each user equipment to the center equipment Means and an optical receiving means for receiving an upstream optical signal from each user equipment, and an optical receiving means for receiving a downstream optical signal in a time domain assigned to each user equipment, and the downstream optical signal itself. Alternatively, an optical transmission unit that modulates a part of the downstream optical signal and transmits the downstream optical signal as an upstream optical signal is provided, and the transmission timing of the downstream optical signal or the upstream optical signal is controlled by at least one of the center device or each of the user devices. A passive point-to-multipoint optical transmission system comprising control means. 2. The passive point-to-multipoint optical transmission system according to claim 1, wherein the control means provides a guard between each downlink optical signal in a downlink frame in which downlink optical signals to each user equipment are time-division multiplexed. A passive point-to-multipoint optical transmission system characterized in that a maximum round-trip propagation delay time between a center apparatus and each user apparatus is set as time. 3. The passive point-to-multipoint optical transmission system according to claim 1, wherein the control means sends the downlink optical signal to each user equipment to the i-th user equipment in a downlink frame time-division multiplexed. The guard time between the downlink optical signal and the downlink optical signal to the (i + 1) th user apparatus is set according to the round-trip propagation delay time between the center apparatus and the i-th user apparatus. Passive point-to-multipoint optical transmission system. 4. The passive point-to-multipoint optical transmission system according to claim 1, wherein the control means controls the time width of the downlink optical signal to each user equipment and the time width of the uplink optical signal from each user equipment. , A value shorter than the maximum round-trip propagation delay time between the center apparatus and each user apparatus is set, and the transmission timing according to the round-trip propagation delay time between each user apparatus is set for the downlink optical signal to each user apparatus. A passive point-to-multipoint optical transmission system characterized by being configured. 5. The passive point-multipoint optical transmission system according to any one of claims 1 to 4, wherein the optical transmission means of the center device uses a phase modulation code to down-transmit light to each user device. A passive point-to-multi, wherein the optical transmission means of each user apparatus is configured to amplitude-modulate the phase modulation code of the received downstream optical signal to generate an upstream optical signal. Point optical transmission system. 6. The passive point-to-multipoint optical transmission system according to claim 1, wherein the optical transmission means of the center device comprises signal light to each user device and modulated light modulated by each user device. Are time-division-multiplexed to generate a downlink optical signal to each user equipment, and the control means sets the time width of the signal light of the downlink optical signal to each user equipment between the center equipment and each user equipment. Is set to the maximum round-trip propagation delay time, and the optical transmission means of each user equipment is configured to modulate the modulated light of the downlink optical signal to generate an uplink optical signal. Type point-multipoint optical transmission system. 7. The passive point-to-multipoint optical transmission system according to claim 1, wherein the optical transmission means of the center device time-division-multiplexes the downstream optical signal to each user equipment, and further in the entire time domain thereof. It is a configuration for superimposing and transmitting direct-current light, the optical transmitting means of each user equipment is a configuration for modulating the received direct-current light to generate an upstream optical signal, and the control means is a timing for generating the upstream optical signal. A passive point-to-multipoint optical transmission system, characterized in that is set in a time domain assigned to each user equipment. 8. The passive point-to-multipoint optical transmission system according to claim 1, wherein the optical transmission means of the center device uses a phase modulation code to generate a downstream optical signal to each user device, and time division is performed. The configuration is to multiplex and transmit, the optical transmission means of each user equipment is a configuration for amplitude-modulating the phase modulation code of the received downlink optical signal to generate an uplink optical signal, and the control means is the uplink optical signal. The point-to-multipoint optical transmission system is characterized in that the generation timing of is set in the time domain assigned to each user equipment.